首页|期刊导航|燃料化学学报(中英文)|基于理论计算的低指数Pt表面过氧化氢氧化还原反应机理研究

基于理论计算的低指数Pt表面过氧化氢氧化还原反应机理研究OA

Theoretical insights into the hydrogen peroxide oxidation and reduction reactions on low-index Pt surfaces

中文摘要英文摘要

过氧化氢(H2O2)的氧化还原反应(HPOR/HPRR)在多种新型电化学能量转换装置中具有重要作用.深入理解其反应机理对于催化剂的设计与性能优化具有关键意义.本工作基于密度泛函理论(DFT)计算,并结合计算氢电极(CHE)模型,系统研究了低指数铂表面(Pt(111)、Pt(100)和Pt(110))上HPOR/HPRR的反应路径.对于HPOR,所有低指数Pt表面均呈现出统一的电位决定步骤,即HOO中间体的电化学氧化.HOO*的结合自由能(ΔGHOO*)可作为HPOR活性描述符,其中,Pt(110)晶面活性最佳,其HOO*吸附自由能(ΔGHOO*)为4.17 eV,最接近理想值4.225 eV.HPRR则遵循化学-电化学(C-EC)路径,其速率决定步骤可能为HO-OH键的化学解离或HO*的电化学还原,具体取决于两者的活化能高低.这些活化能与HO*的结合自由能(ΔGHO*)相关,从而确立ΔGHO*为预测HPRR活性的关键描述符.在活化能相关的火山图中,最优材料的ΔGHO*为0.888 eV,Pt(111)与Pt(100)面接近这一值,因而表现出很高的HPRR活性,尽管仍存在较大的过电位.此外,ΔGHOO*与ΔGHO*之间的线性关系揭示了 HPOR与HPRR之间的热力学耦合,为其在Pt表面上的耦合提供了解释.本研究结果不仅加深了对HPOR和HPRR反应机制的理解,也为过氧化氢相关能量装置与燃料电池中电催化剂的设计提供了重要的理论指导.

Hydrogen peroxide(H2O2)oxidation and reduction reactions(HPOR/HPRR)are pivotal in various innovative electrochemical energy conversion devices.A comprehensive understanding of these mechanisms is critical for catalyst design and performance improvement in these applications.In this work,we systematically investigate the HPOR/HPRR mechanisms on low-index Pt surfaces,specifically Pt(111),Pt(100)and Pt(110),through density functional theory(DFT)calculations combined with the computational hydrogen electrode(CHE)model.For HPOR,all the low-index Pt surfaces exhibit a unified potential-determining step(PDS)involving the electrochemical oxidation of hydroperoxyl intermediates(HOO*).The binding free energy of HOO*(ΔGHOO*)emerges as an activity descriptor,with Pt(110)exhibiting the highest HPOR activity.The HPRR mechanism follows a chem-electrochemical(C-EC)pathway.The rate-determining step(RDS)of HPRR is either the cleavage of the HO-OH bond(chemical)or the reduction of HO(electrochemical),depending on their respective activation energies.These activation energies are functions of the HO* binding free energy,ΔGHO*,establishing ΔGHO* as the descriptor for HPRR activity prediction.Pt(111)and Pt(100)are identified as the most active HPRR catalysts among the studied metal surfaces,although they still experience a significant overpotential.The scaling relationship between ΔGHOO* and ΔGHO* reveals a thermodynamic coupling of HPOR and HPRR,explaining their occurrence on Pt surfaces.These findings provide important insights and activity descriptors for both HPOR and HPRR,providing valuable guidance for the design of electrocatalysts in H2O2-related energy applications and fuel cells.

王琦;陈利芳;丁瑞敏;尹熙

中国科学院山西煤炭化学研究所煤炭高效低碳利用全国重点实验室,山西太原 030001||中国科学院大学化学工程学院,北京 100049中国科学院山西煤炭化学研究所煤炭高效低碳利用全国重点实验室,山西太原 030001中国科学院山西煤炭化学研究所煤炭高效低碳利用全国重点实验室,山西太原 030001中国科学院山西煤炭化学研究所煤炭高效低碳利用全国重点实验室,山西太原 030001

化学化工

过氧化氢氧化反应过氧化氢还原反应低指数铂表面密度泛函理论

HPORHPRRPt low-index surfacesdensity functional theory

《燃料化学学报(中英文)》 2026 (1)

40-54,15

Supported by the Shanxi Province Grant(202203021212007,2023SHB003).

10.1016/S1872-5813(25)60594-9

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